Spatial distribution of ORP and its correlationship with microbial population in a novel horizontal subsurface flow constructed wetland J. Zhai, k.j. Ning, Q. He, H.W.Xiao Chongqing University Jan. 25 th, 2011
Contents Introduction The Constructed Wetland and research methods Results and discussion Conclusions
Introduction Constructed Wetland (CW) : environmental friendly, cost effective for wastewater treatment; good potential for Decentralized system and reuse. Microbial activity is primarily responsible for the removal of carbon and nitrogen in CWs Microbial process is usually limited by relative low Dissolved Oxygen (DO) concentration level A new hybrid constructed wetland system was designed trying to improve the Oxygen Transfer Rate from air to water in a natural way.
The Hybrid CW: VBFW+HSFW system DO control Hydraulic optimization Anaerobic Anoxic / aerobic Pre-treatment Hybrid CWs Post observing site
Vertical Baffled Flow Wetland (VBFW) Inflow Cyperus Alternifolius Outflow 1m in depth
Horizontal Subsurface Flow Wetland (HSFW) Horizontal Subsurface Flow Wetland (HSFW) 4-6 sections of horizontal subsurface wetland beds. Each baffled with 3 walls water flows in a S regime. 0.4m in depth, plant rhizospheric oxygen transfer becomes obvious Natural Aeration Ditches (NADs) water depth: 3~6mm length: 5~7m Function: to improve the contacting chance between air and water
Pilot system 2005-2006, in Chongqing University; Inlet pipe Clean water tank VBFW HSFW Septic tank NAD HSFW
Full-scale system_lugu Lake Designed treatment capacity: 1000 m 3 /d; Technology: VBFW+HSFW Scenic site and High plateau; Nov. 2007 - present
inlet Pre-treatment Sedimentati on pond lago on VBFW HSFW effluent IC
Full-scale system_baishiyi Designed treatment capacity: 500 m 3 /d; Full-capacity operation Small community Technology: VBFW+HSFW April 2008 - present
Full-scale system_baishiyi Inflow Septic tank Stabilization pond Reuse for agricult ure irrigatio n Observing pond HSFW VBFW
Full-scale system_ Wulong Fairy Mountain Designed treatment capacity: 1200 m 3 /d; 1/5 in operation Mountainous site, high altitude Technology: VBFW+HSFW Nov. 2008 - present VBFW Valve wells for drying the VBFW and preventing from clogging
Full-scale system_wulong Fairy Mountain NAD HSFW
Full-scale system_ Qinghe Agro-park Designed treatment capacity: 1500 m 3 /d; Small community Technology: VBFW+HSFW Begin with Jan. 2011
Full-scale system_ Qinghe Agro-park Inflow Screen Septic tank Sediment Pond Stabilization pond Reuse for agriculture irrigation and scenic water body supply Observing pond HSFW VBFW
Full-scale systems LuGu lake CW Baishiyi CW Wulong Fairy Mountain CW Start of operation 11/2007 4/2008 11/2008 Type of site Design wastewater treatment capacity (m 3 /d) Vegetated beds area (m 2 ) Scenic site High plateau; altitude: around 2190m; Small community Non-mountainous site altitude: around 180m; 1000(4000 P. E.) 500 (2000 P. E.) 1200(7000 P. E.) Total: 3716; VBFW: 433; HSFW: 3283; Total: 1172; VBFW: 192; HSFW: 980; Specific area (m 2 m -3 d) 3.72 2.34 2.76 Surface HLR (cm/d) 26.9 42.7 36.3 HRT (h) 44 31 45 Filtration material (size in mm) Gravel (3-20, decrease step by step) Gravel (3-20, decrease step by step) Town in natural conservation area; Mountainous site; Altitude: around 1200m. Total: 3306; VBFW: 1010; HSFW: 2296; Gravel (3-20, decrease step by step) Plants Phragmites Cyperus alternifolius Cyperus alternifolius Internal circulation Operated in winter Non operated Operated in winter and holiday season
Full-scale systems Wulong Fairy Mountain LuGu lake CW Badiyiyuan-Bayixian CW CW Average Parameter Treatment efficiency Influent a Effluent a Eff. of three full-scale systems Influent a Effluent a Eff. applied in south Influent a Effluent a Eff. China Eff. (%) (%) (%) (%) T/ 10.8 -- -- 22.3 -- -- 18.4 -- -- ph 7.2 -- -- 6.3 -- -- 6.9 -- -- COD 132 21 This 84.1 research 246 25.8 tries to 89.5 evaluate 167.3 27.5 83.6 85.7 (mg/l) SS (mg/l) 93 3.2 the performance 96.6 143 7.22 of HSFW 95.0 155.1 on DO 1.6 99.0 96.8 NH 4 -N 10.8 2.2 79.6 34 5.3 84.4 21.9 6.2 71.7 80.5 (mg/l) increasing and its effect on TN (mg/l) -- -- microbial -- -- process. -- -- 48.6 11.6 76.1 76.1 TP (mg/l) 2.9 0.45 84.5 3.8 0.88 76.8 2.1 0.67 68.1 76.5 a Concentrations expressed in mg/l, Mean data (minimum maximum) b National discharge standard of pollutants for municipal wastewater treatment plants, China, Grade 1,Class B (GB 18918,2002). c Value in parenthesis is the limit with ambient temperature higher than 12.
Material and methods 6 7 18 19 30 5 8 17 20 29 4 9 16 21 28 3 10 15 22 27 2 11 14 23 26 1 12 13 24 25 NAD plant s prob e Water level 30cm 20cm Perforate d pipe 60c 180cm m Filler 45cm 40cm
Material and methods CODcr, TN, NH 4 -N, G COD, G TN, G NH4-N (the gradient of the parameters along the flow path in CW) DO, ORP, Specific Oxygen Uptake Rate (SOUR) of the sludge Microbial Population Density (MPD) of the sludge indicated by the amount of phospholipids with simplified PLFA. Pearson Product Correlation Coefficients (r) for correlationship analysis
TN (mg/l) CODcr (mg/l) NH4-N (mg/l) Results and discussion 95.0 90.0 22.00 20.00 85.0 80.0 18.00 75.0 70.0 65.0 16.00 14.00 60.0 12.00 55.0 50.0 NAD HSFW bed 10.00 1 2 3 4 5 6 7 8 9 101112131415161718192021222324252627282930 Sample Point Number NAD HSFW bed 1 2 3 4 5 6 7 8 9 101112131415161718192021222324252627282930 Sample Point Number 26.0 24.0 22.0 20.0 18.0 16.0 14.0 12.0 10.0 NAD HSFW bed 1 2 3 4 5 6 7 8 9 101112131415161718192021222324252627282930 Sample Point Number Concentration profiles of COD and Nitrogen CODcr, NH 4 -N, and TN reduced from 88.7±1.53 mg.l -1, 18.60±1.30 mg.l -1, 20.58±0.63 mg.l -1 to 54.7±3.51 mg.l -1, 13.11±0.58 mg.l -1, 16.83±1.34 mg.l -1 respectively within the studied section of HSFW
ORP (mv) DO (mg/l) Results and discussion Profile of ORP and DO 300.0 4.50 4.00 200.0 3.50 100.0 3.00 2.50 0.0 2.00 1.50-100.0 1.00-200.0-300.0 NAD HSFW bed 1 2 3 4 5 6 7 8 9 101112131415161718192021222324252627282930 NAD (7m) Sample Point Number 0.50 0.00-0.50 NAD HSFW bed 1 2 3 4 5 6 7 8 9 101112131415161718192021222324252627282930 Sample Point Number DO from 0.28±0.09mg/l ----- 3.80±0.11mg/l, increased 3.5mg/l; ORP from +37.3±19.59mV ----- +247.7±22.96mV, increased 210.40mV. HSFW DO declined 3.80±0.11mg/l ----- 0.31±0.18mg/l (5.5m, point 7-11); ORP declined +247.7±22.96mV ----- 71.7±10.60mV(point 9) ----- -102.9±7.55mV (point 13) an aerobic zone 3.5m long (0.5 hour) an anoxic zone of 3.5m long (0.5 hour). the remaining HSFW bed is dominated in anaerobic condition.
SOUR (mg/g Sludge.min) MPD (nmol P/g Sludge) Results and discussion Profile of MPD and SOUR in HSFW bed 0.350 600 0.300 500 0.250 0.200 0.150 0.100 400 300 200 0.050 100 0.000 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 0 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 Sample Point Number Sample Point Number MPD and SOUR decreased dramatically from 457±36.12 nmol P/g sludge and 0.279±0.018 mg O 2 /(g sludge.min) at point 7 to 19±24.06 nmol P/g sludge and 0.015±0.006 mg O 2 /(g sludge.min) respectively at point 30. At the beginning of HSFW bed (from point 7 to Point 10), the SOUR value shows typical aerobic bio-film growing on the gravel surface.
Results and discussion Correlationship analysis r COD NH 4 -N TN ORP DO SOUR G COD * G NH4-N * G TN * G ORP * G DO * SOUR 0.945 0.944 0.970 0.922 0.650 -- 0.805 0.513 0.307 0.807 0.714 MPD 0.964 0.944 0.970 0.926 0.680 0.986 0.776 0.466 0.330 0.776 0.700 ORP 0.955 0.942 0.920 -- 0.875 0.922 0.915 0.460 0.235 -- -- DO 0.744 0.715 0.658 0.875 -- 0.650 0.825 0.114 0.062 -- -- MPD and SOUR have very obvious positive correlativity with r = 0.986 ORP has more positive correlationships with chemical and microbial parameters compared with DO. ORP is a more reasonable parameter to indicate aerobic or anaerobic environment in CWs. The spatial distributions of Microbial Population and microbial activity intensity are closely related to the redox condition in HSFW bed; Biological degradation of organic matters still dominates the microbial process in the studied section of HSFW bed.
Conclusions A seven-meter-long NAD in the novel horizontal subsurface flow constructed wetland can improve the DO concentration in wetland bed creating an aerobic zone of around 3.5m long with HRT of 0.5 hour and an anoxic zone of around 3.5m long. The increased DO concentration can enhance aerobic microbial process and accelerate biodegradation of COD and NH 4 -N consequently. The high correlationship coefficients between ORP and the parameters of microbial activity (r ORP-MPD = 0.922 and r ORP-SOUP =0.926) indicate that microbial activity intensity are greatly influenced by the redox condition in HSFW bed. In the studied section of HSFW bed, bacterial activities for biological degradation of organic matters are still the main microbial process, which exhaust most of the oxygen in water phase.
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